Abstract
We show that every planar triangulation on n > 10 vertices has a dominating set of size 2n/7 = n/3.5. This approaches the n/4 bound conjectured by Matheson and Tarjan [12], and improves significantly on the previous best bound of 17n/53 ≈ n/3.117 by Spacapan [18].
From our proof it follows that every 3-connected n-vertex near-triangulation (except for 3 sporadic examples) has a dominating set of size n/3.5. On the other hand, for 3-connected near-triangulations, we show a lower bound of 3(n — 1)/11 ≈ n/3.666, demonstrating that the conjecture by Matheson and Tarjan [12] cannot be strengthened to 3-connected near-triangulations.
Our proof uses a penalty function that, aside from the number of vertices, penalises vertices of degree 2 and specific constellations of neighbours of degree 3 along the boundary of the outer face. To facilitate induction, we not only consider near-triangulations, but a wider class of graphs (skeletal triangulations), allowing us to delete vertices more freely.
Our main technical contribution is a set of attachments, that are small graphs we inductively attach to our graph, in order both to remember whether existing vertices are already dominated, and that serve as a tool in a divide and conquer approach. Along with a well-chosen potential function, we thus both remove and add vertices during the induction proof.
We complement our proof with a constructive algorithm that returns a dominating set of size < 2n/7. Our algorithm has a quadratic running time.
From our proof it follows that every 3-connected n-vertex near-triangulation (except for 3 sporadic examples) has a dominating set of size n/3.5. On the other hand, for 3-connected near-triangulations, we show a lower bound of 3(n — 1)/11 ≈ n/3.666, demonstrating that the conjecture by Matheson and Tarjan [12] cannot be strengthened to 3-connected near-triangulations.
Our proof uses a penalty function that, aside from the number of vertices, penalises vertices of degree 2 and specific constellations of neighbours of degree 3 along the boundary of the outer face. To facilitate induction, we not only consider near-triangulations, but a wider class of graphs (skeletal triangulations), allowing us to delete vertices more freely.
Our main technical contribution is a set of attachments, that are small graphs we inductively attach to our graph, in order both to remember whether existing vertices are already dominated, and that serve as a tool in a divide and conquer approach. Along with a well-chosen potential function, we thus both remove and add vertices during the induction proof.
We complement our proof with a constructive algorithm that returns a dominating set of size < 2n/7. Our algorithm has a quadratic running time.
| Original language | English |
|---|---|
| Publication date | 2024 |
| Number of pages | 46 |
| DOIs | |
| Publication status | Published - 2024 |
| Externally published | Yes |
| Event | Symposium on Discrete Algorithms - New Orleans, United States Duration: 12 Jan 2025 → 15 Jan 2025 https://www.siam.org/conferences-events/past-event-archive/soda25/ |
Symposium
| Symposium | Symposium on Discrete Algorithms |
|---|---|
| Country/Territory | United States |
| City | New Orleans |
| Period | 12/01/2025 → 15/01/2025 |
| Internet address |
Keywords
- planar graphs
- dominating set
- triangulations
- near-triangulations
- constructive algorithm
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Dive into the research topics of 'Triangulations Admit Dominating Sets of Size 2n/7.'. Together they form a unique fingerprint.Projects
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GAGA: Graph Algorithms with Geometric Applications
Rotenberg, E. (PI)
15/07/2025 → 14/04/2029
Project: Research
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ERCP: Efficient Recomputation for Changeful Problems
Rotenberg, E. (PI), Berg, S. D. (Collaborator) & Hoog, I. V. D. (Collaborator)
01/07/2021 → 30/06/2026
Project: Research
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